US20120163702A1 - Image processing apparatus and image processing method - Google Patents

Image processing apparatus and image processing method Download PDF

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Publication number
US20120163702A1
US20120163702A1 US13/324,042 US201113324042A US2012163702A1 US 20120163702 A1 US20120163702 A1 US 20120163702A1 US 201113324042 A US201113324042 A US 201113324042A US 2012163702 A1 US2012163702 A1 US 2012163702A1
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image
eye
externally
images
taken
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US13/324,042
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Kiyoshi Ikeda
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Sony Corp
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Sony Corp
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    • HELECTRICITY
    • H04ELECTRIC COMMUNICATION TECHNIQUE
    • H04NPICTORIAL COMMUNICATION, e.g. TELEVISION
    • H04N13/00Stereoscopic video systems; Multi-view video systems; Details thereof
    • H04N13/20Image signal generators
    • H04N13/261Image signal generators with monoscopic-to-stereoscopic image conversion
    • HELECTRICITY
    • H04ELECTRIC COMMUNICATION TECHNIQUE
    • H04NPICTORIAL COMMUNICATION, e.g. TELEVISION
    • H04N13/00Stereoscopic video systems; Multi-view video systems; Details thereof
    • H04N13/10Processing, recording or transmission of stereoscopic or multi-view image signals
    • H04N13/106Processing image signals
    • H04N13/111Transformation of image signals corresponding to virtual viewpoints, e.g. spatial image interpolation
    • HELECTRICITY
    • H04ELECTRIC COMMUNICATION TECHNIQUE
    • H04NPICTORIAL COMMUNICATION, e.g. TELEVISION
    • H04N13/00Stereoscopic video systems; Multi-view video systems; Details thereof
    • H04N13/10Processing, recording or transmission of stereoscopic or multi-view image signals
    • H04N13/106Processing image signals
    • H04N13/128Adjusting depth or disparity

Definitions

  • the present technology relates to an image processing apparatus and an image processing method for processing a signal of an image which can be three-dimensionally viewed by a viewer. Especially, the present technology relates to an image processing apparatus and an image processing method for processing an image which is pseudo-3D-generated so as to obtain a three dimensional image which can be viewed with naked eyes.
  • a 3D image which can be three-dimensionally viewed can be provided to an observer by displaying images having parallax to right and left eyes of the observer. It has been expected that a 3D image technique is applied to various fields such as television broadcast, movies, telecommunication, and telemedicine.
  • a time-division stereoscopic image display system that is composed of a combination of a display device and 3D glasses has already been widespread (For example, refer to Japanese Unexamined Patent Application Publication No. 2010-21731).
  • the display device displays a left-eye image and a right-eye image which have parallax alternately on a screen in a particularly short cycle.
  • the 3D glasses have shutter mechanisms which are liquid crystal lenses, for example, and provided to a left-eye part and a right-eye part respectively.
  • 3D glasses of the number of persons who watch contents at the same time should be provided, a person who usually wears glasses has to further wear 3D glasses on the glasses, eyestrain is easily caused by long-time viewing, and a viewed image changes in accordance with a move of a viewpoint of a viewer.
  • it is troublesome to carry shutter glasses as well when we would like to enjoy 3D images on portable information equipment such as a portable disk reproduction device which performs reproduction processing of a disk in which 3D video contents are recorded.
  • An image which is three-dimensionally viewed is basically an actually-taken two-viewpoint image which is composed of a left-eye image and a right-eye image which are obtained by actually taking an object respectively by a left-eye camera and a right-eye camera.
  • the number of viewpoints is increased as four viewpoints or eight viewpoints, for example, and parallax images which are taken from larger number of directions are combined, a more natural three-dimensional image can be viewed not only from the front but also from wider viewpoints.
  • a multi-viewpoint image is composed of images which are actually taken from multiple viewpoints by a plurality of cameras (multi-viewpoint cameras) which are arranged in an array fashion.
  • the number of multi-viewpoint cameras is increased in accordance with the increase of the number of viewpoints, so that the cost of contents production including shooting is increased and a data amount of the contents is increased disadvantageously.
  • the increase of the data amount causes increase of memory, increase of a circuit scale, and the like when 3D images are dealt in portable information equipment such as a portable disk reproduction apparatus, deteriorating portability.
  • an image processing apparatus generating a multi-viewpoint image, including a parallax detection unit configured to receive only one of a plurality of actually-taken images including a left-eye image taken by a left-eye camera and a right-eye image taken by a right-eye camera and detect parallax of the received image so as to generate a parallax map, a first pseudo three-dimensional image generation unit configured to receive the left-eye image taken by the left-eye camera and generate one or more externally-provided or internally-provided images that are taken by a camera externally or internally provided to the left-eye camera, based on the parallax map generated by the parallax detection unit, a first delay unit configured to receive the left-eye image taken by the left-eye camera and output the left-eye image with elapse of delay time that corresponds to time during which the first pseudo three-dimensional image generation unit generates one of the externally-provided images and the internally-provided images, a second pseudo
  • the image processing apparatus of the above embodiment may further include an image composition unit configured to discretely arrange respective pixels of the generated images of multiple viewpoints so as to compose a three-dimensional image.
  • an image processing method generating a multi-viewpoint image, including detecting parallax from only one of a plurality of actually-taken images including a left-eye image taken by a left-eye camera and a right-eye image taken by a right-eye camera so as to generate a parallax map, generating one or more externally-provided or internally-provided images that are taken by a camera externally or internally provided to the left-eye camera, from the left-eye image taken by the left-eye camera, based on the parallax map that is generated in detecting parallax, outputting the left-eye image taken by the left-eye camera with elapse of delay time that corresponds to time during which one of the externally-provided images and the internally-provided images is generated in generating one or more externally-provided or internally-provided images from the left-eye image, generating one or more externally-provided or internally-provided images that are taken by a camera externally or
  • a superior image processing apparatus and a superior image processing method by which a multi-viewpoint image for obtaining a three-dimensional image which can be three-dimensionally viewed with naked eyes can be favorably processed can be provided.
  • a superior image processing apparatus in which a circuit for generating a multi-viewpoint image from left and right actually-taken images is configured to have a smaller circuit scale and smaller memory capacity can be provided.
  • FIG. 1 schematically illustrates the functional configuration of an image processing circuit that generates four viewpoints by pseudo 3D generation from a left-eye image L and a right-eye image R which are respectively acquired by an actual take by a left-eye camera and a right-eye camera;
  • FIG. 2 schematically illustrates the functional configuration of another image processing circuit that generates four viewpoints by pseudo 3D generation from a left-eye image L and a right-eye image R which are respectively acquired by an actual take by a left-eye camera and a right-eye camera;
  • FIG. 3A illustrates a system of multi-viewpoint conversion processing in which images of two viewpoints are converted into images of four viewpoints by using the pseudo 3D generation
  • FIG. 3B illustrates a system of multi-viewpoint conversion processing in which images of two viewpoints are converted into images of four viewpoints by using the pseudo 3D generation.
  • one composite image is generated by discretely arranging respective pixels of images of multiple viewpoints, a viewer with naked eyes can percept a three-dimensional image.
  • a left-eye image and a right-eye image which are respectively acquired by a left-eye camera and a right-eye camera are used as actually-taken images and pseudo 3D generation processing is applied to these actually-taken images so as to obtain an externally-provided image and multi-viewpoint-convert the images of two viewpoints.
  • the pseudo 3D generation processing indicates that depth (parallax) information is obtained from still images taken on two viewpoints for images respectively taken by a left-eye camera and a right-eye camera so as to falsely generate images of multiple viewpoints.
  • Processing respectively performed to the left-eye image and the right-eye image is similar to 2D/3D conversion in which depths of respective objects in a two-dimensional image are estimated so as to convert the image into a pseudo three-dimensional video image.
  • FIGS. 3A and 3B schematically illustrate a system of multi-viewpoint conversion processing in which images of two viewpoints are converted into images of four viewpoints by using pseudo 3D generation.
  • L and R are respectively real left-eye camera and right-eye camera and a left-eye actually-taken image L and a right-eye actually-taken image R can be obtained from respective cameras.
  • an externally-provided image “(LL) left-left” which is taken from a pseudo camera externally provided to the left-eye camera L mentioned above and an internally-provided image “(LR) left-right” which is taken from a pseudo camera internally provided to the left-eye camera L can be obtained.
  • an externally-provided image “(RR) right-right” which is taken from a pseudo camera externally provided to the right-eye camera R mentioned above and an internally-provided image “(RL) right-left” which is taken from a pseudo camera internally provided to the right-eye camera R can be obtained.
  • intervals of respective cameras LL, L, LR, RL, R, and RR may be uniform.
  • FIG. 1 schematically illustrates the functional configuration of an image processing circuit 10 that generates four viewpoints by pseudo 3D generation from a left-eye image L and a right-eye image R which are respectively acquired by an actual take by a left-eye camera and a right-eye camera.
  • actually-taken images of two viewpoints which are the left-eye image L actually taken by the left-eye camera and the right-eye image R actually taken by the right-eye camera are inputted.
  • the parallax detection circuit 12 When a parallax detection circuit 12 receives the left-eye image L, the parallax detection circuit 12 detects depths, that is, parallax of respective pixels and generates a parallax map for one image frame, for example, so as to output the parallax map to a pseudo 3D generation circuit 13 .
  • the pseudo 3D generation circuit 13 generates an externally-provided image from an actual-taken image based on parallax information. Namely, when the pseudo 3D generation circuit 13 receives the left-eye image L, the pseudo 3D generation circuit 13 generates an externally-provided image LL which seems to be taken by a pseudo camera externally provided to the left-eye camera L, based on the above-mentioned parallax map. As the processing of the pseudo 3D generation, enhancement such as enhancing a left edge based on the parallax information is applied, for example, so as to generate the image LL which seems to be taken by the pseudo camera externally provided to the left-eye camera L.
  • the delay circuit 11 When a delay circuit 11 receives the left-eye image L, the delay circuit 11 outputs the left-eye image L with elapse of delay time during which the pseudo 3D generation circuit 13 generates the externally-provided image LL from the left-eye image L and outputs the image LL.
  • a parallax detection circuit 15 receives the right-eye image R, the parallax detection circuit 15 detects depths, that is, parallax of respective pixels and generates a parallax map for one image frame, for example, so as to output the parallax map to a pseudo 3D generation circuit 16 .
  • the pseudo 3D generation circuit 16 When the pseudo 3D generation circuit 16 receives the right-eye image R, the pseudo 3D generation circuit 16 generates an image RR which seems to be taken by a pseudo camera externally provided to the right-eye camera R, based on the above-mentioned parallax map.
  • enhancement such as enhancing a right edge based on the parallax information is applied, for example, so as to generate the image RR which seems to be taken by the pseudo camera externally provided to the right-eye camera R.
  • the delay circuit 14 When a delay circuit 14 receives the right-eye image R, the delay circuit 14 outputs the right-eye image R with elapse of delay time during which the pseudo 3D generation circuit 16 generates the externally-provided image RR from the right-eye image R and outputs the image RR.
  • an image composition circuit 17 When an image composition circuit 17 receives the above-described images L, LL, RR, and R of four viewpoints, the image composition circuit 17 discretely arranges respective pixels of these images based on a predetermined rule so as to generate and output one composite image.
  • the image composition circuit 17 can arbitrarily arrange pixels perform pixel arrangement accompanying parallax adjustment.
  • the arrangement method of pixels of respective viewpoint images is not directly related to the substance of embodiments of the present technology, so that its detailed description is not shown in this specification.
  • the composite image obtained by the image composition circuit 17 is outputted to a screen of a display device such as a liquid crystal display, as a 3D image which can be three-dimensionally viewed by naked eyes.
  • a display device such as a liquid crystal display
  • the composite image is stored in a recording medium after undergoing predetermined signal processing such as encoding.
  • the image processing circuit 10 shown in FIG. 1 has such configuration that the two pseudo 3D generation circuits and 16 are arranged in parallel so as to generate four pieces of parallax data. Further, the image processing circuit 10 includes the parallax detection circuits 12 and 15 which respectively perform parallax detection processing with respect to the left-eye image L and the right-eye image R so as to generate parallax maps, and the pseudo 3D generation circuits 13 and 16 respectively generate externally-provided images LL and RR by using the parallax maps separately generated from the left-eye image L and the right-eye image R respectively.
  • the parallax detection circuit 12 for the left-eye image L and the parallax detection circuit 15 for the right-eye image R have to be separately provided, increasing the circuit scale disadvantageously.
  • a memory for storing the parallax maps respectively generated by the parallax detection circuits 12 and 15 should be provided for each image, increasing memory capacity as well.
  • the present inventor and the like propose that parallax detection is performed with respect to only either one of the left-eye image L and the right-eye image R and an obtained parallax map is used in both cases generating an externally-provided image LL and generating an externally-provided image RR so as to realize reduction of the circuit scale and reduction of memory capacity.
  • FIG. 2 illustrates a configuration example of an image processing circuit 20 realizing reduction of the circuit scale and reduction of memory capacity.
  • actually-taken images of two viewpoints which are a left-eye image L actually taken by a left-eye camera and a right-eye image R actually taken by the right-eye camera are inputted.
  • the parallax detection circuit 22 When a parallax detection circuit 22 receives the left-eye image L, the parallax detection circuit 22 detects depths, that is, parallax of respective pixels and generates a parallax map for one image frame, for example, so as to output the parallax map to each of a pseudo 3D generation circuit 23 and a pseudo 3D generation circuit 26 .
  • the pseudo 3D generation circuit 23 When the pseudo 3D generation circuit 23 receives the left-eye image L, the pseudo 3D generation circuit 23 generates an externally-provided image LL which seems to be taken by a pseudo camera externally provided to the left-eye camera L, based on the parallax map generated by the parallax detection circuit 22 .
  • the delay circuit 21 When a delay circuit 21 receives the left-eye image L, the delay circuit 21 provides outputs the left-eye image L with elapse of delay time during which the pseudo 3D generation circuit 23 generates the externally-provided image LL from the left-eye image L and outputs the image LL.
  • the pseudo 3D generation circuit 26 When the other pseudo 3D generation circuit 26 receives the right-eye image R, the pseudo 3D generation circuit 26 generates an externally-provided image RR which seems to be taken by a pseudo camera externally provided to the right-eye camera R, based on the parallax map generated by the parallax detection circuit 22 , in a similar manner.
  • the delay circuit 24 When a delay circuit 24 receives the right-eye image R, the delay circuit 24 outputs the right-eye image R with elapse of delay time during which the pseudo 3D generation circuit 26 generates the externally-provided image RR from the right-eye image R and outputs the image RR.
  • an image composition circuit 27 When an image composition circuit 27 receives the above-described images L, LL, RR, and R on four viewpoints, the image composition circuit 27 discretely arranges respective pixels of the externally-provided images based on a predetermined rule so as to generate and output one composite image.
  • the image composition circuit 27 can arbitrarily perform parallax adjustment (same as above).
  • the example shown in FIG. 2 employs such configuration that the parallax detection circuit 22 receives the left-eye image L to generate the parallax map and the parallax map is used in both of the pseudo 3D generation circuits 23 and 26 on the left and the right.
  • the right-eye image R is inputted and a parallax map which is used in both left and right pseudo 3D generation is generated may be employed.
  • each of the number of parallax detection circuits and the number of memories for holding the parallax map can be reduced to one, enabling reduction of the circuit scale.
US13/324,042 2010-12-22 2011-12-13 Image processing apparatus and image processing method Abandoned US20120163702A1 (en)

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US10168798B2 (en) * 2016-09-29 2019-01-01 Tower Spring Global Limited Head mounted display

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